SPECIFICATION REDUNDANT POWER SUPPLY HOT-SWAPPABLE BPS-460RDX 6-OUTPUT 460W+460W BEST POWER SOLUTIONS, INC. 2F, NO.196-10, SEC.3, DA-TONG RD., XIZHI DIST., NEW TAIPEI CITY, TAIWAN R.O.C. Tel: 886-2-8647-1188 Fax: 886-2-8647-3322
1.0 General 1.1 Parameter Specifications 2.0 Input Characteristics 2.1 Input Voltage 2.2 Input Waveform 2.3 Input Frequency 2.4 Input Current 2.5 In-Rush Current 2.6 Line Regulation 2.7 Input Leakage Current 2.8 Isolation (Hi-Pot) 3.0 Output Characteristics 3.1 DC Output Characteristics 3.2 Overshoot 3.3 Efficiency 4.0 Time Sequence 4.1 Hold-Up Time 4.2 Power Good Signal 4.3 +5 Volt & +3.3V Power Good Output Rise Time 4.4 Start-Up Time 4.5 Dynamic Load Response Time 5.0 Protection 5.1 Over Power Protection 5.2 Over Voltage Protection 5.3 Short Circuit Protection 5.4 No Load Operation 5.5 5VSB (Standby) 5.6 PS-ON (Remote ON/OFF) 5.7 3.3V Sense 6.0 System Interface Signal 6.1 Power System Fault Signal 6.2 Alarm Beeping Sound
7.0 Physical Characteristics 7.1 Size 7.2 Mounting Requirements 7.3 Weight 7.4 Cooling 8.0 Connectors 8.1 DC Output Wire List 8.2 AC Input 9.0 Environmental 9.1 Temperature 9.2 Relative Humidity 9.3 Altitude 9.4 Shock 9.5 Vibration 9.6 Power Line Transient 9.7 Acoustic Noise 10.0 Regulatory Agency Certification 10.1 RFI/EMI Standards 10.2 Safety Standards 11.0 Reliability 11.1 Mean Time Between Failures (MTBF) 11.2 Warranty
1.0 General This specification describes the physical, functional and electrical characteristics of a redundancy 460+460 watt, 6-output, fan-cooled switching power supply. 1.1 Parameter Specifications Unless specified otherwise, all parameters must be not over the limits of temperature, load and input voltage. 2.0 Input Characteristics 2.1 Input Voltage Normal Minimum Maximum 115 VAC 90 VAC 132 VAC 230 VAC 180 VAC 264 VAC Input voltage range set with a 115/230 VAC selector. 2.2 Input Waveform The unit is capable of operating with a 10% distorted sinewave input as measured by a distortion analyzer. Its flattopping clipped 10% from the peak value of standard sinewave. 2.3 Input Frequency 47 Hz to 63 Hz 2.4 Input current Input Power Vin: 115VAC Vin: 230VAC 640W 7 A 3.5 A 2.5 In-Rush Current 132/264VAC, Full load. Turn off 1 sec; turn on at peak of input voltage cycle. LIMITS No damage shall occur or components over stressed, input fuse shall not blow.
25 Air Ambient cold start. 2.6 Line Regulation LIMITS Full load, +/1% 90/180-132/264 VAC input 2.7 Input Leakage Current Input leakage current from line to ground will be less than 3.5 ma rms. Measurement will be made at 240 VAC and 60Hz. 2.8 Isolation (Hi-pot) 1500VRMS, 50Hz, for one (1) minute between each input AC line and the grounding conductor. 3000VRMS, 50Hz, for one (1) Minute between the input AC lines and secondary low voltage outputs and shields. All isolation transformers will have been tested prior to assembly into a power supply unit. Any such transformers without a grounded shield will be tested to 3750 VRMS. 3.0 Output Characteristics 3.1 DC Output Characteristics To be met under all combinations of loading. Output V1 V2 V3 V4 V5 5VSB Voltage +5V 3.3V +12V -5V -12V Standby Max. Load 40A 20A 30A 0.5A 0.5A 2A Min. Load 0A 0A 1A 0A 0A 0A Max. Power 250W 2.5W 6W 10W 441W Load Reg. +/-5% +5/-3% +/-5% +/-10% +/-10% +/-5% % Cross Reg. +/-5% +5/-3% +/-5% +/-10% +/-10% +/-5% % Line Reg. +/-1% +/-1% +/-1% +/-1% +/-1% +/-1% % Ripple +/-1% +/-1% +/-1% +/-2% +/-2% +/-1% %
Noise +/-1% +/-1% +/-1% +/-2% +/-2% +/-1% % Note 1: The +12 Volt output of the power supply must be capable of 32 Amps peak for 10 seconds. A +/-5% tolerance is permissible. Output voltage is measured at the load and of the output cable. Note 2: Noise bandwidth is from DC to 20 MHz. Note 3: Regulation tolerance shall include temperature change, warm up drift and dynamic load. 3.2 Overshoot Any output overshoot at TURN-ON shall not exceed 5% (+5V/+12V/+3.3V outputs) and 10% (-5V/-12V outputs) of nominal voltage value. 3.3 Efficiency 70% min. at full load test. 4.0 Time Sequence 4.1 Hold-Up Time Unit shall continue to supply regulated DC outputs and power good signal for at least 20 milliseconds at 115/230 VAC full load after a loss of AC input voltage, which shall be represented by a short circuit at the AC input. 4.2 Power Good Signal When the power supply is turned off for a minimum of 1.0 second and turned on, the power-good signal as described below will be generated. The power supply shall provide a power-good signal to indicate proper operation of the power supply. This signal shall be a TTL compatible high level for normal operation; low level for fault conditions. Power-good shall go to a low level at least 1 ms before the +5V output voltage falls below the regulation limits described in 3.1 DC output Characteristics. The operation point used as a reference for measuring the 1ms shall be minimum line voltage and maximum load. All waveform transitions shall be smooth and monotony, i.e. no oscillations. The power-good signal shall stay low (during POWER-ON) until all output voltages are stable within regulation limits. The power-good signal shall have a TURN-ON delay greater than 100 ms but less than 500 ms. 4.2.1 Fan-out
Power-Good output circuit shall consist of an active pull down component and a passive pull up resistor. Power-Good output voltage to be met under recommended loading conditions. IoH= -140uA Min. IoL= 2.8mA Min. LIMITS VoH= 2.7V Min. VoL= 0.4V Min. 4.3 +5 V & +3.3V and Power Good Outputs Rise Time 4.3.1 +5 V & +3.3V Output Rise Time The +5 Volt and +3.3 Volt output shall have a turn-on rise time of less than 100ms under all load conditions. Rise time is measured between 0.0 and 2.48/4.75 volts. The +5 V and +3.3V output shall not vary from a smooth curve by more than 0.5 VP-P during turn-on and turn-off. +5v, +3.3V 0.5Vp-p max. 0.5Vp-p max. Rise Time < 5us 2.5v P/G CV 4.4 Start-up timing All outputs shall be stable and in regulation in less then 2.0 second under all load and line conditions. Start-up time is measured between the AC turn-on and 4.75 volts on +5v output. 4.5 Dynamic Load Response Time Transient response is measured by switching the output load from 80 to 100 to 80 percent of its full value at a frequency of 100 Hz and 50% duty cycle, step load change is 0.5A/us, The magnitude Vr is less than +/- 5% of +5V and +12V outputs, the recovery time Tr is less than 1ms. 5.0 Protection 5.1 Over Power Protection This power supply shut down all DC outputs when +5 Vdc and +12 Vdc
outputs are overloaded to the limit. The power supply logic shall latch into the off state requiring a power on cycle to be performed by the operator. The power supply will turn-off within 20 ms of the occurrence of the overload. The -5 Vdc and -12 Vdc outputs will be internally current limited. LIMIT 90/180 VAC input When output power is over to 120% 5.2 Over Voltage Protection The power supply shall latch off if the +5 VDC or 3.3VDC or +12 VDC maximum voltages exceeds the limits shown. The AC must be recycled to restart. +5 VDC All operating LIMITS 6.25 VDC +/- 0.65 VDC +3.3 VDC All operating LIMITS 4.10 VDC +/- 0.40 VDC +12 VDC All operating LIMITS 13.6-15.6 VDC 5.3 Short Circuit Protection A short circuit placed on any output shall cause no damage to this unit. 5.4 No Load Operation When primary power is applied, with no load on any output voltage, no damage or hazardous conditions shall occur. In such a case, the power supply shall power up and stabilize. However, minimum load required 3A for +5V and 1A for +12V. 5.5 5VSB (Standby) The 5VSB output is always on (+5V Standby) when AC power is applied and power switch is turned on. The 5VSB line is capable of delivering at a maximum of 5A for PC board circuit to operate. 5.6 PS-ON (Remote ON/OFF)
PS-ON is an active low signal that turns on the entire main power rail including 3.3V, 5V, -5V, 12V & -12V power rails. When this signal is held by the PC board or left open circuited, outputs of the power rails should not deliver current and should be held at a zero potential with respect to ground. Power should only be delivered to the rails if PS-ON signal is held at ground potential. This signal should be held at +5VDC by a pull-up resistor internal to the power supply. Power On P1-PIN #14 PS-ON Power Switch P1-PIN #14 PS-ON ON L ON IN OFF H ON IN OFF X ON OUT OFF X OFF X 5.7 3.3V Sense A remote 3.3V sense line can be added to the P1 connector Pin2 to allow for accurate control of the 3.3VDC line directly at motherboard loads. Due to potential voltage drops across the connector and traces leading to the motherboard components, it may be advantageous to implement a 3.3V sense line that remotely monitors the 3.3VDC power level at the load on the motherboard. 6.0 System Interface Signal 6.1 Power System Fault Signal The Hot-Swap Redundant Power Supply shall give fault signal (an open collector output) that will indicate the status of the power supply operation. If one of the power supply unit shut down, the power fault signal could be generated. This signal shall be high level for normal operation; Low level for fault conditions. 6.2 Alarm Beeping Sound The alarm system monitors the power supply failure and provides alarm to indicate the status of the power system. By checking the LED on the power supply, end users will be able to locate the defective power unit. The alarm system will give a beeping sound to indicate the power supply failure until that particular power unit is replaced. Beeping sound could be suspended before the failure power supply unit replaced by pressing the Alarm Switch. 7.0 Physical Characteristics
7.1 Size 150*86*193mm 7.2 Mounting Requirements See Figure 6 7.3 Weight 3 Kg 7.4 Cooling Fans: SUNON (KD1208 PQB1-A), equivalent or better. Airflow from the power supply should be in exhaust direction and shall be rated at 24 cfm minimum. 8.0 Connections 8.1 DC Output Wire List +For ATX Mother Board Connector Output Wire Color Wire Size ATX 24 Pin P1-1 +3.3V BRN 16 AWG P1-2 +3.3V BRN 16 AWG P1-3 GND BLK 18 AWG P1-4 +5V RED 18 AWG P1-5 GND BLK 18 AWG P1-6 +5V RED 18 AWG P1-7 GND BLK 18 AWG P1-8 PW-OK ORG 18 AWG P1-9 5VSB PURPLE 18 AWG P1-10 +12V YEL 18 AWG P1-11 +12V YEL 18 AWG P1-12 +3.3V BRN 16 AWG P1-13 +3.3V BRN 16 AWG P1-14 -12V BLUE 18 AWG P1-15 GND BLK 18 AWG P1-16 PS-ON GREEN 18 AWG P1-17 GND BLK 18 AWG P1-18 GND BLK 18 AWG P1-19 GND BLK 18 AWG P1-20 NG NG NG P1-21 +5V RED 18 AWG P1-22 +5V RED 18 AWG
P1-23 +5V RED 18 AWG P1-24 GND BLK 18 AWG 8PIN 12V FOR P4 P1-1 GND BLK 18 AWG P1-2 GND BLK 18 AWG P1-3 GND BLK 18 AWG P1-4 GND BLK 18 AWG P1-5 +12V YEL 18 AWG P1-6 +12V YEL 18 AWG P1-7 +12V YEL 18 AWG P1-8 +12V YEL 18 AWG P11 P12 Pn-1 +5V RED 22 AWG Pn-2 COM BLK 22 AWG Pn-3 COM BLK 22 AWG Pn-4 +12V YEL 22 AWG P13 P14 Pn-1 +12V YEL 18 AWG Pn-2 COM BLK 18 AWG Pn-3 COM BLK 18 AWG Pn-4 +5V RED 18 AWG P15 P16 Pn-1 +12V YEL 18 AWG Pn-2 COM BLK 18 AWG Pn-3 COM BLK 18 AWG Pn-4 +5V RED 18 AWG P17 P18 Pn-1 +12V YEL 18 AWG Pn-2 COM BLK 18 AWG Pn-3 COM BLK 18 AWG Pn-4 +5V RED 18 AWG 8.2 AC Input IEC 320 power inlet with EMI filter. 9.0 Environmental 9.1 Temperature
9.1.1 Operating 50 to 122 F (0 to 50 C). Derate Linearly to 50% at 70 C 9.1.2 Non-Operating -4.0 to 140 F (-20 to 60 C) 9.2 Relative Humidity 9.2.1 Operating 20 to 90 % non-condensing at 104 F (40 C). 9.2.2 Non-Operating 5 to 95 % non-condensing at 122 F (50 C). 9.3 Altitude 9.3.1 Operating Sea level to 10,000 feet. 9.3.2 Non-Operating Sea level to 40,000 feet. 9.4 Shock 9.4.1 Operating The power supply shall exhibit no sings of damage or degradation of performance when subjected to a shock of 5g`s for 11 ms, with a 1/2 sine wave for each of the perpendicular axes X, Y and Z. 9.4.2 Non-Operating The power supply shall exhibit no sings of damage or degradation of performance when subjected to a shock of 30g's for 11 ms, with a 1/2 sine wave for each of the perpendicular axes X, Y and Z. 9.5 Vibration 9.5.1 Operating The power supply shall be subjected to a vibration test consisting of a 10 to 500 Hz sweep at a constant acceleration of 0.5g for duration of one (1) hour for each of the perpendicular axes X, Y and Z. The output voltages shall
remain within specification. 9.5.2 Non-Operating The power supply shall be subjected to a vibration test consisting of a 10 to 300 Hz sweep at a constant acceleration of 2.0g for duration of one (1) hour for each of the perpendicular axes X, Y and Z. The power supply shall not incur physical damage or degradation of any characteristics below the performance specifications. 9.6 Power Line Transient 9.6.1 Drop Out With a full cycle input voltage dropout at 50Hz, the unit shall operate within the prescribed voltages with a dropout cycle repetition rate of 500ms. Full load, Nom. Input AC Voltage LIMITS Meet all requirements 9.6.2 Transient Voltage Spikes The unit shall meet the following standards, The IEEE Standard 587-1980 for surge withstand capability under categories A and B. The crest value of the first half peak of the injected Ring wave (0.5/10us) and Bi-wave (1.2/50us) will be 3K volts open circuit and 3KA (8us 20us) short circuit. IEC 801-2 (ESD) to a level of 8KV contact, and 15K air discharge without causing the device(s) to fail the test. IEC 801-4 (EFT) on the power lines and all I/O cables to a level of 2.5KV without causing the Device(s) to fail the test. IEC 801-5 Surge immunity measurement on the input power source of 2.5KV. All output shall be stable and in regulation. 9.7 Acoustic Noise The power supply shall be tested in accordance with the ANSIS12.10-1985 standard specifications. The "A" weighted overall sound pressure level as well as individual octave band levels from 63 Hz to 16,000 Hz is measured with the noise meter placed 1 meter from the nearest vertical surface of center of fan installed in power supply. LIMITS 115 VAC Input, full load of +5V Acoustic noise is 40 db maximum
0.5A of +12V. Octave Band Center Frequency (Hz) A-Weighted 125 250 500 1k 2k 4k 8k 16k Max. Sum 20 36 42 42 42 36 30 20 40dBA 10.0 Regulatory Agency Certification 10.1 RFI/EMI Standards The power supply, when installed in system, shall MEETS with the following radiated and conducted emissions standards: a) FCC part 15, Subpart A, Class A computing devices. b) CISPR22 (EN55022) Class A. c) VCCI Class 2. These limits shall be met with a margin of at less 6dB at all applicable frequencies. The unit shall comply with the above limits when tested under all normal working conditions and with all interface cables connected. 10.2 Safety Standards The power supply shall be MEETS with the following safety standards, a) UL 1950 (Information Processing/Business equipment). b) CSA C22.2, NO. 234-M90 level 6 (Safety of component, power supplies) or CSA C22.2, NO. 950-M89. c) TUV Certification to IEC 950 lst edition with Amendment #1, #2, and EN60950 d) CB Certificate & Test report deviation for the Nordic countries. e) CE Certificate & Test report. 11.0 Reliability 11.1 Mean Time Between failures (MTBF) Using MIL217E the calculated MTBF = 100,000 hours at 25 C 11.2 Warranty Two (2) years manufacture's warranty Date code indicating week and year of manufacture.